基于UVIS/HDAC和TWINS Lyman-α数据的3-15 RE地球外逸层日面h密度剖面

IF 1.7 4区地球科学 Q3 ASTRONOMY & ASTROPHYSICS

Annales Geophysicae Pub Date : 2022-05-06 DOI:10.5194/angeo-40-271-2022

J. Zoennchen, H. Connor, Jaewoong Jung, U. Nass, H. Fahr

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引用次数: 2

摘要

摘要利用UVIS/HDAC (UVIS -紫外成像光谱仪)观测地球黄道日侧3-15地球半径(RE)之间的外大气层Lyman-α柱强度对卡西尼号上的HDAC -氢-氘吸收电池Lyman-α光度计进行了分析，得出了地球黄道日侧在这个径向范围内的中性外逸层h密度剖面。这些数据是在1999年8月18日卡西尼号绕地机动时测量的，并由Werner等人(2004)发表。本研究将Werner et al.(2004)发表的白天侧HDAC Lyman-α观测数据与基于twin (Two广角成像中性原子光谱仪)Lyman-α观测数据(Zoennchen et al.， 2015)的三维h密度模型计算的Lyman-α强度进行了比较。两种Lyman-α谱都表现出非常相似的径向依赖性，特别是在3-8 RE之间。在3.0-5.5 RE撞击距离之间，twin和UVIS/HDAC的Lyman-α观测都存在于黄道日侧。在这个重叠区域，假设由于可比较的空间天气条件，两者的外逸层相似，对HDAC剖面和计算的TWINS剖面进行了交叉校准。作为交叉校准的结果，每秒计数和瑞利之间的转换因子fc=3.285计数s−1 R−1，被确定为这些HDAC观测。利用这一因子，我们从UVIS/HDAC观测中得出了地球黄道日面的径向H密度剖面，该剖面将10 RE下的中性H密度限制为35 cm−3。此外，与3-7 RE(≈r-2.37)的距离相比，在8 RE(≈r-3)以上的距离上，径向h密度的下降速度更快。8re以上中性氢损失的增加可能表明，由于外逸层氢原子与磁层外太阳风离子的电荷交换相互作用增加，在9 - 11re的磁层顶附近(太阳亚点附近)和更远的地方，氢电离率更高。

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Terrestrial exospheric dayside H-density profile at 3–15 R_E from UVIS/HDAC and TWINS Lyman-α data combined

Abstract. Terrestrial ecliptic dayside observations of the exospheric Lyman-α column intensity between 3–15 Earth radii (RE) by UVIS/HDAC (UVIS – ultraviolet imaging spectrograph; HDAC – hydrogen-deuterium absorption cell) Lyman-α photometer at CASSINI have been analyzed to derive the neutral exospheric H-density profile at the Earth's ecliptic dayside in this radial range. The data were measured during CASSINI's swing-by maneuver at the Earth on 18 August 1999 and are published by Werner et al. (2004). In this study the dayside HDAC Lyman-α observations published by Werner et al. (2004) are compared to calculated Lyman-α intensities based on the 3D H-density model derived from TWINS (Two Wide-angle Imaging Neutral-atom Spectrometers) Lyman-α observations between 2008–2010 (Zoennchen et al., 2015). It was found that both Lyman-α profiles show a very similar radial dependence in particular between 3–8 RE. Between 3.0–5.5 RE impact distance Lyman-α observations of both TWINS and UVIS/HDAC exist at the ecliptic dayside. In this overlapping region the cross-calibration of the HDAC profile against the calculated TWINS profile was done, assuming that the exosphere there was similar for both due to comparable space weather conditions. As a result of the cross-calibration the conversion factor between counts per second and rayleigh, fc=3.285 counts s−1 R−1, is determined for these HDAC observations. Using this factor the radial H-density profile for the Earth's ecliptic dayside was derived from the UVIS/HDAC observations, which constrained the neutral H density there at 10 RE to a value of 35 cm−3. Furthermore, a faster radial H-density decrease was found at distances above 8 RE (≈r-3) compared to the lower distances of 3–7 RE (≈r-2.37). This increased loss of neutral H above 8 RE might indicate a higher rate of H ionization in the vicinity of the magnetopause at 9–11 RE (near subsolar point) and beyond, because of increasing charge exchange interactions of exospheric H atoms with solar wind ions outside the magnetosphere.

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来源期刊

Annales Geophysicae 地学-地球科学综合

CiteScore

4.30

自引率

0.00%

发文量

审稿时长

2 months

期刊介绍： Annales Geophysicae (ANGEO) is a not-for-profit international multi- and inter-disciplinary scientific open-access journal in the field of solar–terrestrial and planetary sciences. ANGEO publishes original articles and short communications (letters) on research of the Sun–Earth system, including the science of space weather, solar–terrestrial plasma physics, the Earth''s ionosphere and atmosphere, the magnetosphere, and the study of planets and planetary systems, the interaction between the different spheres of a planet, and the interaction across the planetary system. Topics range from space weathering, planetary magnetic field, and planetary interior and surface dynamics to the formation and evolution of planetary systems.